System and method for providing network-based technical support to an end user

ABSTRACT

An embodiment of a method for obtaining customer support includes transmitting parameters specific to an end user product to a network-based application operable to dynamically generate a web page instructive of a solution to a problem associated with the end user product based on the parameters; receiving an interactive link to the dynamically generated web page; and browsing the dynamically generated web page by selecting the interactive link. The method may further include implementing the solution by performing steps instructed in the web page. An embodiment of a system is operable to perform operations comprising receiving parameters specific to an end user product; dynamically generating a web page instructive of a solution to a problem associated with the end user product based on the parameters; generating an interactive link to the dynamically generated web page.

CROSS REFERENCE TO RELATED PATENT APPLICATIONS

This application claims the benefit of U.S. Provisional Application No. 60/821,124, filed Aug. 1, 2006, U.S. Provisional Application No. 60/821,537, filed Aug. 4, 2006, and U.S. Provisional Application No. 60/882,928, filed Dec. 30, 2006, which are incorporated herein by reference for all purposes.

BACKGROUND

Internet service providers (ISPs) provide connections to the Internet for millions of customers, and the untapped market is still substantial. ISPs today may offer one or more of cable, phone, and Internet service. In addition to providing the underlying cable, phone, or Internet service, most ISPs also provide a host of other services to their customers, such as email, personalized homepages, web page hosting, and other content and/or value-added resources. Quality of Service (QoS) is an important determinant of customer satisfaction with an ISP. Customers today have come to expect high-quality service virtually all the time. If expected QoS is not met, customers expect the problem to be fixed promptly. Unfortunately, for a number of reasons ISPs are often unwilling or unable to adequately address customers' complaints when they have arisen.

Of course, no matter how hard an ISP tries, technical, and other problems, occur, which reduce the perceived QoS. For one thing, the cause of the customer's problem may not be the ISP equipment or service, but rather the customer's computer, software, or other equipment. The reduction in QoS can range from simply a slow connection speed, to inability to access a particular service (e.g., email), up to outright failure to connect to the Internet. In a perfect world, these problems would not occur, but reasonable Internet users understand and accept that these problems will occur from time to time. When expected QoS is not met, customers often call on their ISP to fix the problem (even if the cause of the failure is not the ISP). The ISPs that are able to promptly and professionally fix the customer's problems will tend to keep their customers happier. As a result, ISPs that can promptly and professionally address customers' QoS complaints stand to succeed, whereas ISPs that cannot fix these problems in a quick, efficient, low-cost, professional, and thorough manner will tend to lose out to their competition.

Accordingly, ISPs typically provide resources that customers can call on when problems arise. Through these resources, customers can typically notify the ISP of the problem and attempt to get the problem fixed. For example, a telephone number (e.g., a 1-800 number) may be provided with which the customer can contact a technical help desk and talk to a technical support person who can walk the person through a series of steps to attempt to fix the problem. In addition, the ISP may provide a self-help Web site with technical support information. The customer may be able to type in a problem report (also referred to as an “incident” report) to be sent over the network to a technician who will reply with a suggested fix. The ISP may even dispatch a technician to the customer's home.

Unfortunately, these conventional methods have significant limitations. ISPs typically cannot afford to send a technician to every customer's home when they complain of service problems; such an approach would be cost prohibitive. With regard to Web-based support, conventional self-help Web sites often leave customers confused and bewildered, due to their lack of knowledge in computer, software and network technology. Furthermore, customers and support technicians (e.g., telephone-based, chat-based, email-based) often have inadequate or inappropriate tools to address the customer's particular problem. Support technicians typically do not have a complete view of the customer's computer system, and must rely on the customer's knowledge of his/her own system, which may be very limited.

Most frustrating, after all attempts to address a customer's problem fail, the ISP often simply notifies the customer that the service provided by the ISP is functioning properly, and the customer's problem is not the ISP's responsibility. Problems that are not due to the ISP's equipment or service are often referred to as “out-of-scope” with respect to the ISP, and the customer is left stranded to fend for himself, or to chase down other vendors to find a solution.

All of the above situations result in unnecessary costs, wasted time, and all too often a very dissatisfied customer. When overall customer satisfaction drops, the ISP generally experiences a high rate of customer churn (i.e., customers leaving the ISP for a competing ISP), an increased cost of acquiring new customers, and the cost of re-acquiring former customers. In addition, when customer satisfaction falls, the ISP typically has significant resistance among its existing customer base to adopt new, advanced services such as Voice over Internet Protocol (VoIP) service, video on demand, music on demand, or other services that might otherwise generate new revenue.

As such, systems and methods are needed to address the above problems and other like issues.

SUMMARY

An embodiment of a method for obtaining customer support includes transmitting parameters specific to an end user product to a network-based application operable to dynamically generate a web page instructive of a solution to a problem associated with the end user product based on the parameters; receiving an interactive link to the dynamically generated web page; and browsing the dynamically generated web page by selecting the interactive link. The method may further include implementing the solution by performing steps instructed in the web page. Transmitting parameters specific to the end user product comprises transmitting a differential set of parameters relative to a base set of parameters.

The method may further involve receiving a hyperlink from a technical support agent during a chat session between the end user and the technical support agent. Browsing the dynamically generated web page may include browsing the web page in a graphical user interface window pane in a window that includes a chat window pane presenting the chat session. The web page may include content specific to the parameters of the end user's product. The content may include one or more of an image of a component specific to the end user's product parameters, audio specifically related to the end user's product parameters, media content specifically related to the end user's product parameters. The method may further involve receiving one or more other interactive links to respective other web pages instructive of the solution.

An embodiment of the method further includes storing the one or more other interactive links in a first folder containing links to web pages instructive of solutions that have not been viewed. The method may still further include entering key words descriptive of a problem scenario of the end user's product; transmitting the key words to the network-based application operable to determine a one or more targeted possible causes for the described problem, wherein the one or more targeted possible causes are specific to the parameters of the end user's product, and wherein the one or more targeted possible causes are determined by searching a knowledge base of problem scenarios gathered from a plurality of other end user's to derive one or more general possible causes; and filtering the one or more general possible causes with the parameters of the end user's product; and receiving a description of at least one of the one or more targeted possible causes.

An embodiment of a system is operable to perform operations comprising receiving parameters specific to an end user product; dynamically generating a web page instructive of a solution to a problem associated with the end user product based on the parameters; generating an interactive link to the dynamically generated web page. The process may further include identifying a set of possible causes of the problem based on key words descriptive of the problem; filtering the set of possible problems with the parameters, to derive one or more possible causes that are specific to the end user product. Identifying a set of possible causes may involve searching a knowledge base of problem scenarios identified in a plurality of other end user products to find problem scenarios that relate to the key words. Dynamically generating a web page may involve selecting content for the web page based on the parameters of the end user product.

The system-implemented process may further involve transmitting the interactive link to the end user. Transmitting the interactive link to the end user may involve transmitting the interactive link when the end user is not online. The process may further include dynamically generating a plurality of web pages instructive of possible solutions to the problem. The process may further include storing the plurality of web pages remotely from the end user's computer system, wherein storing further comprises storing the plurality of web pages in association with a customer support subscription of the end user. The system-implemented process may further involve storing web pages of new solutions in a first folder and storing web pages of previously used solutions in a second folder.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates an exemplary operating environment in which a technical support platform may be utilized in accordance with one embodiment.

FIG. 2 illustrates a distributed technical support platform including user interfaces, a technical support services architecture, applications and data, wherein the user interfaces are adapted to interact with various modules of the technical support services architecture, in accordance with the embodiment of FIG. 1.

FIG. 3 illustrates a technical support and services platform facilitating network-based technical support and services related thereto, in accordance with one embodiment.

FIGS. 4-5 illustrate exemplary schemes for providing technical support for a particular problem incident based on an aggregation of problem information and solutions developed from other technical support jobs performed in response to other problem incidents reported across a general population of end user computer systems.

FIG. 6 illustrates an exemplary scheme for delivering network-based technical support to an end user in accordance with one embodiment.

FIG. 7 illustrates a configuration difference generation scheme in accordance with one embodiment.

FIGS. 8-11 are flowcharts illustrating processes for registering a customer for technical support and providing and receiving the technical support using a technical support platform according to one embodiment.

FIGS. 12-24 are snapshots of exemplary graphical user interfaces for use with the end user client application and/or agent side application.

FIG. 25 depicts a general computing device upon which a technical support and services platform, or portions thereof, may be implemented, accessed, and/or executed.

While the invention is amenable to various modifications and alternative forms, specific embodiments have been shown by way of example in the drawings and are described in detail below. The intention, however, is not to limit the invention to the particular embodiments described.

DETAILED DESCRIPTION

Embodiments of the present invention relate to a client application providing a user with services to interact with a network-based agent and a server-based technical support platform providing technical support to the user, whereby the user can fix technical problems with the user's computing system. The client application can automatically generate a profile of the user's system configuration, including hardware and software parameters, and transfer the profile to a network-based technical support platform. The technical support platform provides a filtered set of the problem resolution data from the knowledge base, which is filtered based on the user's system configuration. These filtered resolution result sets can then be viewed and utilized by the user to solve problems, provide answers to application usage questions and distribute online tutorials that further educate the user on their system and its operations.

Through the client application, the user can enter into an online chat session with a technical support agent who has access to the technical support services architecture, including the user's profile, whereby the agent may identify resolutions specific to the user, thereby eliminating the need for the user to have detailed operating knowledge of the user's computing system. System-specific resolutions and help can be pushed to the client during the chat session or when the user is offline. The resolutions can be presented as a hyperlink, which the user can select, to cause the client application to browse a resolution presented on a web page stored at the technical support services architecture. The client application stores newly pushed resolutions for the user to access via the client interface. Solutions can be saved in a folder for long term saved solutions, so that the user can access and use them later. Saved resolutions can be designated as the user's preferred fixes (e.g., “My Fixes”).

In various embodiments, the technical support services architecture saves the user's current system configuration profile and last most recent (also defined as “last known good”) system configuration profile. The technical support platform compares the current and most recent profiles to determine differences in the user's system configurations. The differences and/or the last most recent configuration profile are sent, along with the current system configuration profile, to the client. Through the client, the user can view the current system configuration and the previous system configuration and compare the two configurations.

In a particular embodiment, the client application is a Flash®-based application that presents a graphical user interface (GUI) to the user. The Flash© application responds to user input, such as mouse clicks on buttons that are present on the GUI. Through the buttons, the user can access different services of the Flash® application, which can include running a computing system PC Configuration Detector, a chat session interface, a resolutions access interface, and a help function. The Flash® application communicates via the network with the agent-side computer and/or the technical support platform to present the user with various resources, information, and services. For example, the chat button of the Flash® application enables the user to interact with an agent online. The user can download new drivers, tutorials, videos, help, frequently asked questions (FAQs), and so on. The Flash® application can provide filtered help that is specific to the user's computing system configuration, and delivers dynamically built “how-to's”, fixes and pre-defined solution sets targeted directly at the specific needs of the user.

As such, and in contrast to conventional Flash applets, the Flash® application consumes network (e.g., web) services. Within the Flash® application applets and/or scripts are run in response to user input and/or received network data. The client Flash® application communicates with the technical support platform via Extensible Markup Language (XML) data transfer. The Flash® application performs transactional data manipulation with Extensible Stylesheet Language Transformation (XSLT) to transform XML documents to user viewable text and interactive graphics.

One embodiment includes a “thin” client application that facilitates end-user communication and interaction with a services oriented architecture that contains information for use in providing or obtaining technical support. An embodiment of the services oriented architecture is made up of a large portal infrastructure. In some embodiments, data stores of the services oriented architecture comprise a warehouse of information gathered from multiple technical support incident reports and the jobs carried out to resolve them. Modules (e.g., applets, applications, tools, or utilities) of the services oriented architecture enable the client application to access the technical support information in the warehouse.

An embodiment of a client application is logically part of a technical support platform. An embodiment of a technical support platform is implemented according to an n-tier (e.g., three-tier) client-server model. In this embodiment, the platform is modular, and any of the n tiers can be upgraded independently of the other tiers. In a three-tier approach, a user interface tier executes on one or more user computers (e.g., desktop PC), a technical support services architecture executes on one or more network-based application servers, and data is stored by and accessed from one or more network-based database server(s). Technician user computer interfaces and/or end user computer interfaces are adapted to communicate with one or more applications of the technical support services architecture.

The architecture may be implemented using a virtual machine, such as .NET from Microsoft™ Corporation, or Java Virtual Machine from Sun™. Data may be stored in databases in accordance with any number of database models, such as flat, hierarchical, network, relational, object-oriented, or others. By way of example, but not limitation, Microsoft Structured Query Language (SQL), Oracle™ or MySQL databases may be used. Servers and their related services may be implemented using Microsoft's Internet Information Services (IIS) or Apache Hypertext Transport Protocol (HTTP) Servers, or others as appropriate to a particular implementation.

Various embodiments of the present invention relate to a network-based platform configured for providing technical support to customers. The technical support platform includes a technical support services architecture that is accessible by different types of users. In some embodiments, the technical support services architecture can be used by technical support entities providing technical support on behalf of multiple different service providers (SPs), independent software vendors (ISVs) and original equipment manufactures (OEMs). Scalability can be achieved by developing a knowledge base of technical support information from a general population of computer systems, and making the knowledge base accessible to multiple technical support entities whereby the information can be applied to particular problem incidents. In addition, third party (e.g., ISV, OEM, SP) applications and data can be integrated with the technical support services architecture to extend its capabilities and functionality. The technical support platform may be implemented in a distributed architecture and does not require a LAN based configuration to support its operations.

Some embodiments include a client module on the user's computer operable to interact with a technical support services architecture. Using technical information, such as client computer configuration and state, the client module and the technical support services architecture can interactively identify potential causes for technical problems, and determine potential solutions to the technical problems. These potential solutions can be implemented during a technical support interaction or job. Technical support solution sets and problem scenarios of the technical support services architecture can be dynamically updated with information captured from technical support interactions, which can be analyzed for frequency of occurrence and applied to the general customer base. A variety of application programming interfaces (APIs) and Web services are provided to support numerous communication modes between support technicians and end users. The APIs and Web services allow for integration with third party (e.g., SP—specific) APIs and drivers.

The technical support services architecture may be provided transparently to customers of service providers (SP), whereby the technical support platform is viewed as part of the SP's technical support. Alternatively, the technical support platform may be provided as a separate resource for technical support. In any event, the technical support platform is comprehensive with regard to the scope of problems that the platform may address. For example, the technical support platform may be operable to address “in-scope” problems, which are problems that arise from the SP's products or services, as well as “out-of-scope” problems, which are problems that do not arise as a result of the SP's products or services. For example, an “out-of-scope” problem may be a problem with the customer's computer hardware or software that is not provided by the SP.

Some embodiments of the technical support platform facilitate problem resolution by providing a number of architectural layers of application interfaces and technical support data. The technical support data includes, in part, a historical compilation of problem data, possible solutions, and a knowledge base. At the time of a technical support interaction, end-user computer technical information can be used to determine a cause of the problem, and can be mapped to problem information in the historical compilation of problem data. Based on the mapping, a proposed solution can be selected from a set of solutions, and can be provided to the end-user computer. Technical support solution sets and problem scenarios can be dynamically updated with knowledge captured from real time technical support interactions. Technical support solution sets and problem scenarios can be analyzed for frequency of occurrence and applied and reused more generally with respect to a broader client base. As such, embodiments of the technical support platform are scaleable and extensible.

Prior to describing one or more preferred embodiments of the present invention, definitions of some terms used throughout the description are presented.

DEFINITIONS

The term “service provider” refers broadly to any provider of products or services to one or more customer(s). Service providers include, without limitation, Internet service providers (ISPs), network service providers (NSPs), and broadband service providers (BSPs), cable providers, digital subscriber line (DSL) providers, digital satellite link providers, wireless service providers, and telecommunications providers (e.g., regional telephone service providers).

The term “incident” refers to an instance of a reported problem.

The term “technical support job” or simply “job” refers to the processes carried out from the time a problem is reported to a final disposition of the problem. A job may span multiple interactions between the end-user and a support agent. Typically a job is uniquely associated with an identifier, such as a ticket, to allow for referencing the job later.

The term “end-user” (or end user) refers to an individual who is using a product or service for which customer or technical support may be provided.

The term “customer” refers broadly to any consumer of services or products. Customers can include, without limitation, individuals or entities which may have more than one end user, such as households with one or more end-users, home businesses, small businesses, colleges, universities, government organizations, and for-profit and nonprofit companies.

The term “quality of service” refers broadly to the degree of excellence of a service or product. Quality of service is not limited to quality of service as that term is commonly understood in the TCP/IP protocol and/or packet-switched networks and/or computer networking. Rather, quality of service more generally relates to an end user's satisfaction or dissatisfaction with the performance of a product or service.

The term “module” refers broadly to a self-contained functional component. A module may be composed of software, hardware, or firmware (or any combination thereof). Modules are typically functional components that can generate useful data or other output using specified input(s). An application program (also called an “application”) may include one or more modules, or a module can include one or more application programs.

The terms “connected” or “coupled” and related terms are used in an operational sense and are not necessarily limited to a direct connection or coupling.

The phrases “in one embodiment,” “according to one embodiment,” and the like generally mean the particular feature, structure, or characteristic following the phrase is included in at least one embodiment of the present invention, and may be included in more than one embodiment of the present invention. Importantly, such phrases do not necessarily refer to the same embodiment.

If the specification states a component or feature “may”, “can”, “could”, or “might” be included or have a characteristic, that particular component or feature is not required to be included or have the characteristic.

The terms “responsive” and “in response to” includes completely or partially responsive.

The term “computer-readable media” is media that is accessible by a computer or computer-like device (e.g. game console, IP devices), and can include, without limitation, computer storage media and communications media. Computer storage media generally refers to any type of computer-readable memory, such as, but not limited to, volatile, non-volatile, removable, or non-removable memory. Computer storage media may be magnetic, optical, or other format. Communication media refers to a modulated signal carrying computer-readable data, such as, without limitation, program modules, instructions, or data structures.

Exemplary System

One embodiment is a platform that includes an Internet-based service and support architecture that enables the efficient delivery of technical support to a consumer (e.g., Internet user or ISP customer). In this embodiment, a “thin” client software package facilitates communication and interaction with a technical support services architecture. The technical support service architecture may include a large portal infrastructure that contains information for use in providing or obtaining technical support. The information may be viewed as a warehouse of information gathered from multiple technical support incident reports and the jobs carried out to resolve them.

In some embodiments, the architecture is implemented according to an n-tier (e.g., three-tier or multi-tier) client-server model. As such, the architecture is modular, and any of the n-tiers can be upgraded independently of the other tiers. In a three-tier or multi-tier approach, a user interface tier executes on one or more user computers (e.g., desktop PC), a technical support services architecture executes on one or more network-based application servers, and data is stored by and accessed from one or more network-based database server(s). Technician user computer interfaces and/or end user computer interfaces are adapted to communicate with one or more applications of the technical support services architecture.

The architecture may be implemented using a virtual machine, such as .NET from Microsoft™ Corporation, or Java Virtual Machine from Sun™. Data may be stored in databases in accordance with any number of database models, such as flat, hierarchical, network, relational, object-oriented, or others. By way of example, but not limitation, Microsoft Structured Query Language (SQL), Oracle™ or MySQL databases may be used. Servers and their related services may be implemented using Microsoft's Internet Information Services (IIS) or Apache Hypertext Transport Protocol (HTTP) Servers, or others as appropriate to a particular implementation.

FIG. 1 illustrates an exemplary operating environment 100 in which a technical support platform may be implemented and utilized in accordance with one embodiment. End-users communicate over networks using their computer systems 102 to access customer support centers 104 and/or a services-oriented architecture 106. Different end users may communicate over different service provider (SP) networks, such as service provider network 108 a through service provider network 108 n, where the labels ‘a’ and ‘n’ have no inherent relationship.

Each network 108 represents a logical network that is provided, owned, managed, and/or maintained by a service provider. Of course, a service provider may actually use one or more other service providers' network(s) in providing service to the end user computer system 102. For example, a service provider may contract with wholesale network service providers and/or have peering arrangements with backbone networks or other arrangements whereby traffic through a SP network 108 is routed through other provider networks. Each network 108 can include the Internet (or a portion thereof), a Voice over Internet Protocol (VoIP) network, or other networks or sub networks that the end user may access. Importantly, communication via the networks 108 may be wireless, wired, or any combination thereof.

End user computer systems 102 typically include a computer, such as, but not limited to, a personal computer (PC), and one or more peripheral devices, such as a printer, fax machine, external mass storage device (e.g., CD ROM, disk drive). It will be understood by those skilled in the art that in general, the customer may utilize any type of computing device, such as, but not limited to, a laptop computer, a handheld computer, or an Internet-enabled cellular telephone. The end user computer system 102 may represent or be part of a home or business local area network (LAN). End user computer systems 102 typically include one or more communications devices or adapters to connect to the service provider network 108. Other network components, such as a router/firewall or a broadband modem may be communicably coupled to computers in the system 102 to provide for network 108 communication, data security, network address translation (NAT), or communication between end user computers on a LAN.

Accordingly, the end user generally makes use of multiple components in end user computer system 102. Of course, for numerous reasons, at any given time, the components (e.g., hardware devices, software applications) of the end user computer system 102 or the SP network 108 may have technical problems that render the quality of service to the end user less than satisfactory. In these situations, the end user can obtain technical support from one or more sources through an end user client 109. For example, end user system 102 a includes end user client 109 a and end user system 102 n includes 109 n. The end user clients 109 execute on a computer of the end user's system 102. The end user clients 109 typically include, at least in part, a client interface 111 and one or more applications or applets 113. The interface 111 is an interface to the services oriented architecture 106 and the applications 113 provide functionality related to obtaining customer support from the architecture 106 and customer support agents 110.

For example, through the interface 111 a, the client 109 a can contact customer support agents who provide customer support through customer agent computer systems 110 a at one or more customer support center 104 a. Similarly, the client 109 n can contact customer support agent systems 110 n associated with customer support center 104 n. The customer support agents can provide services and data to assist the end user in identifying the cause of technical problems and in determining potential solutions.

In these and other embodiments, in addition to, or as an alternative to, contacting customer support agent's end user clients 109 may access the services-oriented architecture 106 for technical support, including assistance with products and services associated with their computer system 102. As discussed further below, the client interfaces 109 are adapted to communicate with modules of the services oriented architecture 106. For example, the end user can access “intelligent and/or interactive self-help” tools executing on the services oriented architecture. In addition, the end user client interfaces 109 and a customer support agent interfaces of the customer support agent computer system 110 can access a chat or messaging service provided by the services oriented architecture, whereby the end user can chat or message a customer support agent.

Although specific embodiments of the services oriented architecture 106 are described herein with regard to providing technical support services for a computer system, it is to be understood that other embodiments of the services oriented architecture 106 can relate to providing customer support for a wide variety of products and services. By way of example, but not limitation, end users may need assistance in fixing, assembling or troubleshooting automobiles, home/office appliances, machines, tools, household products, toys, or other products they use or own. The customer agents can assist the end users in detecting problems, determining a solution, and implementing the solution. Although embodiments can be beneficially applied to many areas of customer support, embodiments described herein relate to the providing of technical support for end users' computer systems 102.

Although only two end user computer systems 102 are shown in FIG. 1, in actual operation there will be many more (e.g. thousands or millions) end user computer systems 102. In addition, although the same numerical labels may be used to call out multiple modules, devices or systems, this is merely for convenience of description, and does not imply that these modules, devices or systems are identical. For example, in general end user computer systems 102 will have different hardware, software and/or have different configurations.

The term support center 104 refers to a logical organization of customer support agents and does not imply that the customer support agents are necessarily physically located in the same location. As such, the customer support agent computer systems 110 may or may not be geographically near each other, or even in the same building for each support center 104. For example, different ones of the customer support agents using computer systems 110 a (i.e., the customer support agents associated with support center 104 a) may be located in Los Angeles, Calif., Kansas City, Mo., and Anchorage, Ak. In this situation, customer support requests from end users 110 a may be selectively routed to the customer support agents in each of the cities based on various criteria, such as availability, expertise, geographic proximity, network proximity, or network load balancing considerations.

Although each service provider network 108 is shown as associated with one support center in FIG. 1, it is to be understood that embodiments are not limited to one-to-one relationships. In general, a support center 104 a may provide services for numerous SPs in addition to SP network 108 a, and SP network 108 a may utilize multiple support centers 104 in addition to support center 104 a.

The services-oriented architecture 106 provides automated customer support services. In various embodiments, the services-oriented architecture 106 is accessible by end users as well as customer support agents. The services-oriented architecture 106 may be implemented in one or more server computers or other computing devices. The services-oriented architecture 106 provides access to various customer support applications 112 and data 114, which can be used by end users and customer support agents. The services-oriented architecture 106 also provides mechanisms through which end users and agents can communicate with each other.

The services-oriented architecture 106 generally supports a technical or customer support platform that is scaleable and extensible to provide customer support with respect to numerous different types of products (or services) within a category of products (or services). For example, embodiments described below relate to providing technical support to identify and solve problems in numerous different end user computer systems, even though different end user systems may have different configurations of hardware and software. Information learned from end user systems (e.g., from the clients 109), such as problem scenarios and solutions, can be advantageously applied to or stored in the services-oriented architecture 106, where it can be used by other end users or customer support agents.

Support centers 104 can subscribe to the services-oriented architecture 106. In some embodiments, knowledge acquired by different support centers, such as support center ‘n’ and support center ‘a’, can be used by the other(s). Embodiments of the customer or technical support platform are described in further detail below and further illustrate the general application or leveraging of knowledge from individual customer support interactions to the wider community of end users and customer support agents.

Other users may access the services-oriented architecture 106 through other user computer systems 116. Other computer systems 116 may communicate with the services-oriented architecture 106 over another network 118 as shown, or the other user computer systems 116 may communicate over one of the service provider networks 108. Other users may be managers or administrators of the services-oriented architecture 106. For example, administrative users may upload new applications 112 or data 114 through the services-oriented architecture. New applications 112 or data 114 may then be accessed by end users and customer support agents.

Generally, end user computer systems 102, customer support agent computer systems 110 and other user computer systems 116 provide interfaces to the service-oriented architecture 106. Each of the computer systems generally has a browser application, as well as other application programs and/or applets that enable access to and communication functionality with the services-oriented architecture 106.

FIG. 2 illustrates a technical support platform 200 in accordance with the embodiment of FIG. 1 and other embodiments. Whereas the embodiment of FIG. 1 may generally be applicable to providing customer support with respect to all types of products or services, the embodiment of FIG. 2 is described with respect to systems and methods for providing technical support with respect to end users' computer systems.

In this regard, the technical support services architecture 206 is one particular embodiment of the service-oriented architecture 106. Support technician interface 1 (210 a), support technician interface 2 (210 b), through support technician X (210 x) are interfaces that could be used in customer support agent computer systems 110 a through customer support agent computer systems 110 n (FIG. 1). End user interface 1 (202 a), end user interface 2 (202 b) through end user interface n (210 n) are particular embodiments of end user interface 111 a through end user interface 111 n. Also shown in the system of FIG. 2 are an administrator user interface 216 and manager user interface 218.

The technical support services architecture 206 provides automated technical support services to end user interfaces 202 and support technician interfaces 210, by in part, providing access to applications 214 and data 216 for use in providing technical support. More specifically, the technical support services architecture 206 includes a number of functional modules that facilitate the provisioning of technical support services. In the illustrated embodiment, the technical support services architecture includes one or more application programming interfaces (APIs) 220, communications utilities 222, drivers 224, self-service tools 226, management tools 228, and third party integration tools 230.

With further regard to the end user interfaces 202, support technician interfaces 210, administrator user interface 216, and/or manager user interfaces 218, in one embodiment these interfaces are included in respective client applications executing on the respective computer systems. In these embodiments, a client application typically includes applets, applications, other executables and/or data that enable the various computer systems (e.g., end user computer systems, technical support agent computer systems, etc.) to contact, communicate with, and use the applications of, the technical support services 206. Typically different client applications reside on the technical support agent computer system, the end user computer system, the management computer system, and the administrative computer system, due to the different responsibilities of each of these users. As is discussed further below, the various client applications can be deployed to the respective user computer systems by the technical support services architecture (e.g., by the management tools 228).

APIs 220 include programming interfaces and/or web interfaces to one or more of the applications 212 and/or tools, utilities or other modules of the architecture 206. Examples of applications and corresponding interfaces are a chat application and chat integration API, and an electronic mail (email) application and an email interface. In these examples, and as discussed in further detail below, support technicians and end users can communicate with each other by sending messages through the chat application and the email system. APIs 220 may also include interfaces that allow managers, administrators, and/or support technicians to add third party applications and data to the technical support services architecture 206. Numerous other APIs may be included, embodiments of which are further described below.

Communications utilities 222 include functionality supporting communication applications including chat, email, instant messaging and others. For example, communications utilities 222 can include an email exchange server, point-of-presence (POP)/simple mail transport protocol (SMTP), and Short Message Service (SMS), as well as telephone communications support such as Internet Protocol Telephony (IPT) and Automatic Call Distribution (ACD). Drivers 224 include one or more drivers for determining how the one or more databases 214 will communicate with other systems such as manager interfaces 218 or administrator interfaces 216. For example, the drivers 224 may support Microsoft's Structured Query Language (SQL) database calls and/or Oracle database calls.

Self-service tools 226 include one or more tools that can be used by the end user without the assistance of a support technician. Examples of self-service tools 226 include, but are not limited to, key word searches for searching databases 214 for topical information, frequently asked questions (FAQs), or forums. As is discussed further below, key word searches are targeted to the end user computer system's particular hardware and software configuration.

Management tools 228 include applications, applets and other modules that administrative users or managers can use to manage aspects of the technical support services architecture. Management tools 228 may provide functionality for updating, adding or deleting applications 212 or data 214 and/or their associated APIs, communications utilities and drivers. In addition management tools 228 may include a program that deploys the client applications (e.g., end user applications 113, FIG. 1) to the associated users.

In an alternative embodiment, the appropriate client applications (e.g., end user applications 113, FIG. 1) can be deployed to end users by the associated support centers. In other embodiments, the SPs themselves may provide the client applications through other mechanisms, such as by Internet download, or by sending a compact disc (CD) through the mail. Regardless of the means by which the client application is provided, the client applications are operable to contact and access the technical support services architecture 206 and/or the associated SP support center.

Third party integration tools 230 include APIs, drivers, and/or other modules for updating, adding, and/or deleting third party tools on the technical support services architecture 206.

Knowledge base (KB) system & tools 232 provides tools (e.g., applications, applets, scripts, programs, etc.) related to processing of content. By way of example, but not limitation, KB system & tools 232 can include programs for filtering, building, generating, searching, formatting, etc. content. Content can include, without limitation, text, images, graphics, video, audio, dynamic web pages or web page scripts (e.g., Java scripts). In various embodiments, the content processed by KB tools 232 related to instructional technical support content, such as images of computer components (e.g., cables, printers, monitors, routers, etc.), step-by-step instructions to solve a technical problem, and so on. Such content is typically embodied in dynamically generated web pages accessible by the end user client.

One example of a KB tool 232 is a web page generator that dynamically generates web pages that describe technical problems (e.g., scenarios, causes, symptoms) and/or instruct an end user on how to solve technical problems. As another example, KB tools 232 may include a configuration difference generator that is operable to determine differences between system configurations. Other examples of KB tools are a problem searching module and problem filtering module, which may be used by an end user or agent to search on and filter a set of previously identified solutions in a problem set data store.

Other tools 234 provide other functions (e.g., in the form of applications, applets, scripts, programs, etc.) to end users, technical support agents or other users. Examples or other tools 234 are third party support tools and remote control, whereby an agent can remotely control the end user's computer. For example, the agent can use remote control to operate the input devices (e.g., mouse and keyboard).

As yet another example, other tools 232 may include functions to gather and analyze technical support data (e.g., problem scenarios, configurations, solutions, etc.) from technical support agents associated with different service providers and/or customer support centers. In this regard, the technical support service architecture 206 can capture data related to particular customers, client system configurations and/or particular technical problems reported by customers and end users. The technical support services architecture 206 can correlate problem data to identify problematic scenarios or configurations that have been observed in multiple technical support jobs in response to incident reports submitted by the general population of end users.

When a recurring technical problem is identified, a problem identifier can be stored (e.g., in a data store 214) along with one or more criteria that defines the problem and one or more possible causes to the problem. Problem scenarios may also be recorded in relation to identified problems. In addition, the technical support service architecture 206 can identify commonly implemented and successful solutions, and store the solutions in association with identified technical problems and/or system configurations. In this manner, recurring and common problems and fixes can be learned and provisioned on a broader scale to many or all subscribing technical support centers and utilized by the general population of technical support agents and the general population of end users. As such, problems and solutions developed for end users of one service provider can be applied to other end users, and even end users subscribing to network service from other service providers (SPs).

Accordingly, one feature of the technical support services architecture 206 is an ability to develop one or more knowledge bases that include information about technical problems, system configurations and solutions, and continually update the knowledge bases based on actual technical support interactions. In this embodiment, the SP customer support centers can register with the technical support services architecture 206 to gain access to the knowledge bases that are maintained by the architecture 206. In this fashion, the SP support centers and the technical support services architecture 206 may be viewed as forming a symbiotic relationship, in which both benefit from the other.

For example, during a performance of a technical support job between a technical support agent and an end user, the agent may search in a set of pre-developed solutions at the technical support services architecture. The pre-developed solutions may reside, for example, in a data store 214 and may be stored in association with previously identified problems and/or system configurations.

Embodiments of the technical support platform 200 can be implemented in a distributed architecture. For example, portions of the platform may be distributed among the technical support agent computer system (e.g., a technician/agent user client application), the end user computer system (e.g., an end user client application), and the technical support services architecture 206. In other words, portions of the technical support platform may be resident upon computing devices that are geographically or logically separated. A distributed technical support platform 200 can provide customers with a transparent, open, scalable, fault tolerant support system.

In some embodiments, the interface used by technical support agents is a web interface that can be accessed through a browser on the agent's computer system. In these embodiments, the technical support and services platform includes a web based interface through which technical support agents can access other resources and applications in the technical support and service platform. The interface for administrative and management users may also include a web interface accessible through browsers on administrative and management users' systems. In such embodiments, the technical support agents, administrators and managers can access the platform at any location that has an Internet connection.

FIG. 3 illustrates one embodiment of a technical support and services platform 300 facilitating end user technical support. The technical support and services platform 300, and portions thereof, may be embodied on one or more client computers, server computers, database servers, and databases. In the embodiment illustrated, the technical support and services platform 300 includes five logical layers: user interfaces 302, communication 304, middle tier 306, application programming interface (API) 308, and data 310. Within each layer, data and/or functionality are provided that together form an integrated, scaleable, and extensible technical support framework and service delivery platform for handling many technical problems that may arise, and for “learning” about new problems and their solutions as they are discovered. Clients can access the technical support and services platform 300 via a network using interfaces provided by the technical support platform 300.

For example, the user interface layer 302 includes a number of interfaces through which a user (e.g., a customer, end user or agent) client accesses the technical support platform 300. An end-user interface 312 is provided by a client application, and represents the interface with which the end user interacts while using the technical support and services platform 300. In some embodiments, the end-user interface 312 is implemented as a browser with one or more applets that access a web portal, described further below. As such, the end-user interface 312 can provide personalized and customizable capabilities to the end user.

Localized client application support interfaces include a technical user interface 314, a management user interface 316, and an administrative user interface 318. These interfaces can be used by technical users (e.g., technicians), managers, and administrative users, respectively, for maintaining components of the technical support platform, obtaining reports of technical support data, and others. The end-user interface 312 and the client activities interfaces can transfer data bi-directionally to each other. As such, data transfer to the end-user interface 312 may be pushed or pulled. Conversely, data can be pushed or pulled to or from the technical user interface 314, the management user interface 316, and/or the administrative user interface 318.

Customer and client administrative modules can be accessed via administrative interfaces. In the illustrated embodiment, an internal system administrative interface 320 and an external administrative interface 322 are provided that can be accessed via a browser with remote client application support.

The communications layer 304 incorporates tools for accessing various modes of communication through which users (e.g., customers, technicians, managers, and administrators) interact with the technical support platform 300 and each other. Brokers manage user access to these tools. One or more intelligent and/or interactive self-service support tools 324 are made available by an end user application broker. Self-service support tools 324 can include filtered-help, offline (disk resident) content, interactive decision tree based drill-downs, web-based frequently asked questions and answers (FAQs), forums, and/or advanced search functions. Other self-service tools may be identified and implemented by those skilled in the art.

The communication layer 304 also typically includes communication modules and interfaces. Communication modules and interfaces can include, by way of example, but not limitation, an e-mail interface 326, such as Microsoft Exchange or POP3/SMTP, a chat interface 328, and a remote (or remote control) management interface 330. Other interfaces can be provided to support other modes of communication. The communication modules provide functionality for the customer and technician to communicate or interact via the associated communication mode. For example, the e-mail interface 326 enables e-mail communication between the customer and a technician.

Telephony support modules, such as phone tier 1 module 332 and phone tier 2 module 334 provide modular interfaces to live telephone technicians. In this embodiment, the phone tier 1 module 332 and the phone tier 2 module 334 can and/or may provide for communication over Voice over IP (VoIP). The phone tier modules provide various telephone agent functionality, such as, but not limited to, VoIP services, virtual Private Branch Exchange (PBX), and/or automatic call distribution (ACD). As such, for example, technical agents can be remotely located, and still have calls routed to them. As another example, in response to receiving a customer service support call, the phone tier modules can sequence through a list of telephone agents until one is reached.

The middle tier layer 306 provides transaction management functionality for managing transactions and data transfer between the user interface layer 302 or the communication layer 304 and the API layer 308, or for data transfer between applications. The modules at the middle tier layer 306 provide various functions to facilitate communication and data transfer, such as, but not limited to, data formatting, timing, and encapsulation. A services platform manager module 336, a communication transaction manager module 338, and a client transaction manager module 340 handle data transfers related to varying types of levels of interaction with the platform 300. For example, the services platform manager 336 handles data transfer or exchange to and from web services provided by the platform. The communication transaction manager 338 handles communications from server side transaction objects. The client transaction manager 340 handles Extensible Markup Language (XML) exchanges with the client modules. A system administration and reporting manager module 342 in the middle tier layer 306 manages interactions with the lower level layers that relate to administrative tasks and report generation.

The API layer 308 provides lower level interfaces through which higher level (e.g., user interfaces 302, communication layer 304) layers access applications and/or data of the technical support platform 300. For example, the API layer 308 includes a client web portal API 344 through which the end user can interface with web portal integration tools using the end user interface 312. External application integration module interfaces include an e-mail system API 346, a chat system API 348, and a remote system API 350, which correspond to the e-mail interface 326, the chat interface 328, and the remote management interface 330, respectively.

The API layer 308 also provides for integration with third party applications and data. A third party application integration module 352 enables third parties (e.g., SPs) to integrate third party-specific applications with the technical support platform 300. Similarly, a third party data integration module 354 enables third parties to integrate third party-specific data with the technical support platform. The third party applications and data can be accessed through the other communication modes, such as e-mail, chat, and remote management. Thus, the third party applications and data can extend the capabilities of the technical support platform.

The data layer 310 provides multiple data sets to keep track of numerous different types of data associated with the technical support platform. End user subscription information is stored in an end user subscription database 356. In addition, the end user subscription database 356 may store end user identification information, user component/configuration data, associated SP provider identifier(s), subscription terms, subscription prices, subscription services, and other customer information. Described further below is an embodiment in which the client outputs configuration data (e.g., system-specific parameters) for storage in the end user subscriptions 356 where they can be retrieved by technical support agents.

A knowledge base 358 includes data relevant to technical support. In one embodiment, the knowledge base (KB) includes a compilation of data gathered from actual problem reports or complaints. The knowledge base 358 is an electronic catalogue (e-catalogue) of numerous previously identified problem scenarios, problematic equipment, problematic configurations, or other data. The knowledge base 358 may be divided into a static portion and a dynamic portion. The static portion includes data that has been validated for accuracy and in general will not be changed; rather the static knowledge base data is intended only for read only access. The dynamic portion of the knowledge base 358 can change, often during real time technical support interactions. Dynamic knowledge base data may be updated as new information is gathered, and may change until it is validated or otherwise determined to be satisfactory for use in other technical support interactions.

Independent application databases also include solution sets 360 and pre-disposition solutions 362. Solution sets 360 are solutions that have been verified as proper for associated problem(s) and/or system configurations. As such, each of the solutions in the solution sets 360 may include an indication of the related problem or problems and/or system parameters characterizing the computer system(s) to which the solution set applies. The pre-disposition solutions 362 include potential solutions that have not been verified as working solutions, but rather they are solutions that have been proposed and may still be changing, based on new information related to the problem or results from implementing the proposed solutions. In one embodiment, while they are being worked on and/or validated, pre-disposition solutions are only accessible by the technician at the technical support center who is familiar with the problem. However, in other embodiments, such as one shown in FIGS. 4-6, described below, pre-disposition solutions may be available to technical support agents who can try using the pre-disposition solutions and report the results of their use.

In one embodiment pre-disposition solutions 362 are unstable solutions (i.e., they may change). When a pre-disposition solution becomes stable (e.g., verified as a valid solution), the pre-disposition solution is approved for application to a wider population of technical agents and end-users. Approved solutions in the pre-disposition solutions set 362 are moved into the solutions set 360. Because the solutions in the solution set 360 have been verified, these solutions can be deployed or made available more globally to all subscribing technical support centers.

Optimized data stores are included in the technical support platform 300 for storing application and reporting data. These data stores may be multi-application internal data stores 364, multi-application external data stores 366, and cross-platform reporting tools 368. The technical support platform 300 also includes a set of database drivers 370 for API support.

In the embodiment of the technical support platform 300 of FIG. 3, one or more modules of the communications layer 304, the middle tier layer 306, and the API layer 308 may logically or physically form a technical support services architecture or other services-oriented architecture. The technical support service architecture may or may not also include the data layer 310. For example the data layer 310 may be included in the technical support services architecture with the other layers, or the data layer 310 may be logically or physically separate from the other layers, but accessible by the other layers.

FIG. 4 illustrates an exemplary scenario in which problems and solutions are identified and developed in a global problem and solution development process 402. Also illustrated is a specific technical support problem and solution determination process 404 that attempts to provide support for a specific end user 416 by making use of identified problems and solutions developed in the global problem and solution development process 402. Generally, during the specific technical support problem and solution determination process 404 one or more targeted possible problems and solutions are determined based on the particular end user's computer system configuration and vetted problems 406 and vetted solutions 407 developed and validated during the global solution development process 402.

The global problem and solution development process 402 is ongoing and may be viewed as a by-product or aggregation of many specific technical support jobs. More concretely, technical support agents 408 are regularly interacting with end users 410 during technical support jobs, wherein the agents 408 may identify new problems and/or develop new solutions to problems in the end users' 410 computer systems. The agents 408 and end users 410 may be associated with any number of service providers (e.g., ISPs, NSPs, wholesale providers, enterprise service providers, etc.). As such, problems identified and solutions generated by the agents 408 comprise a service provider-agnostic, heterogeneous solution set, meaning that the solutions developed relate to a wide variety of different system configurations, platforms, platforms, users, organizations and others.

The problems identified by and the solutions developed by the technical support agents 408 may be new; i.e., these solutions have not been previously identified and stored for later reuse. For example, a technical support agent 408 may not find a problem reported by an end user 410 in the knowledge base 356. As another example, a technical support agent 408 may not find a solution to a particular problem or for a particular system configuration in the solutions set 360 (FIG. 3). The agent 408 will then work with the end user 410 to fully describe the problem, including identified causes, if any, and/or develop a new solution that solves the problem for the end user's 410 system configuration.

Although a newly identified problem may have been described for a particular end user incident, the description (e.g., symptoms, possible causes) may not be described in a way that it can or should be made available to other agents 408 or end users 410. For example, the problem description may not have taken into account other symptoms that would help identify the problem. Similarly, although a new solution may work for a particular end user 410, initially the solution has not been fully tested to determine if the solution can or should be applied more globally to a wider population of end users.

As such, new problems and new solutions are first proposed for application to a wider population. Proposed problems are submitted to a dynamic region of the knowledge base 358 where they can be tested, reapplied by agents in technical support scenarios and validated by administrators. After the proposed problems have been tested and have become static (i.e., no further changes), the vetted problems 406 are moved to the static region of the KB 358. The problems 406 may be stored as data objects that include a problem identifier, description, and one or more possible causes.

Solutions 412 are proposed for use by the general population of end users and agents. They are potentially applicable to a wider customer, agent and configuration base. Proposed solutions 412 are stored in the pre-disposition solution set 362 where they can be further tested, reapplied and validated. Possible dispositions of further testing of solutions are deletion of the proposed solution 412, further monitoring, or approval for broader application to the general end user population. While in the pre-disposition solution set 362 the proposed solutions 412 are vetted through testing and analysis to ensure that the solutions work consistently and have been associated with the appropriate problems and/or system configurations. The agents 408 can search for and use proposed solutions 412 that may be applicable to a system configuration or problem being experienced by an end user 410. The agents 408 can report on the results of using proposed solutions 412. Administrators may also test proposed solutions 412 and report results or findings. Reported results are reviewed to determine the disposition of proposed solutions 412. The amount of analysis and testing of the proposed solutions 412 may vary from system to system.

When proposed solutions 412 are approved for broader application to the global end user population, the vetted solutions 407 are stored in the globally accessible solutions set 360. The vetted solutions 406 are stored in such a way that they can be later retrieved based on the problem they solve and/or the configuration of the system that they are relevant to. For example, the vetted solutions may have a “problem” data field that enables searches of the solutions set 360. The solutions 406 may include a “configuration” data field that specifies configuration parameters relevant to the solution.

In one embodiment, a specific incident targeted solution determination process 404 can make use of vetted problems in the static region of the KB 358 and technical solutions previously vetted and stored in the solution set 360. In the targeted solution determination process 404 a specific end user 416 outputs a system configuration file 418 that includes system-specific parameters 420 characteristic of the end user 416 computer system. The configuration file 418 is transmitted to a specific agent 422 and/or the end-user subscriptions 356 where it is stored. In the embodiment illustrated, the configuration file 418 is stored in the end-user subscriptions 356 and retrieved from the end-user subscriptions 356 by the agent 422. The configuration file 418 is typically stored in association with the specific end user's 416 associated subscription. However, in other embodiments, the configuration file 418 is sent directly to the agent 422.

As mentioned, the system-specific parameters 420 characterize the end user's 416 computer system and present a generally complete view of the end user's 416 computer system, including the hardware and the software parameters, to the agent 422. The specific agent 422 is typically remote from the specific end user 416. It should be understood that although the configuration file 418 is sent to a specific agent 422, if the end user 416 works with a different agent (e.g., in a subsequent technical support session), the configuration file 418 will be available to the different agent via the end-user subscriptions 356.

The embodiment shown in FIG. 4 depicts agent-facilitated help, wherein the agent 422 uses information about the end user's computer system to assist the end user 416 in determining the cause of a problem and one or more targeted solutions. Based on information from the end user 416, including the system-specific configuration 418, the specific agent 422 generates problem descriptors 424 related to a problem or an identified cause of a problem. The key words 424 are used to search the static region of the knowledge base 358 for problems that relate to the key words 424.

An alternative embodiment involves end-user intelligent self-help. In this embodiment, the specific end-user 416 enters keywords that are used to search for targeted problems in the knowledge base 358. Only problems that relate to the end user's 416 system-specific parameters will be searched for. For example, if the end user has an Apple Macintosh™ computer, only problem related to Apple Macintosh™ will be found. Problem identifiers, description (e.g., symptoms, severity, secondary problems), and one or more possible causes are returned to the specific end-user 416.

In the particular embodiment shown in FIG. 4, an unfiltered set of problems 425 is determined from problems (either static or dynamic) the KB 358. The unfiltered problem set 425 may be viewed as a problem set that is relevant to the problem, but applies to the general end user 410 population, rather than the specific end user 416. As such, the system-specific parameters 420 of the configuration file 418 are applied to the unfiltered problem set 425 to filter out problems that do not apply to the specific end user computer system configuration. In the illustrated embodiment, the end user client application filters the unfiltered problem set 425. In another embodiment, illustrated in FIG. 6, the agent may carry out the filtering, based on an agent-assess configuration file.

With further regard to filtering the problem set 425, filtering may be performed using system-specific parameters 420 of the configuration file 418. Of course some system-specific parameters 420 may match parameters associated with problems in the problem set 425, while others do not. As such, in some embodiments the level of filtering can be set to allow for tolerance. For example the agent 422 may set the filter tolerance such that only a certain number of parameters must match. As another example, the agent 422 may set the filter tolerance such that only the hardware parameters (or only a certain number of hardware parameters) must match. As yet another example, the filter tolerance may specify particular parameters of the system-specific parameters 420 that must be in the technical solutions 428.

The result of filtering on the end user configuration is a targeted, filtered problem set 426 of one or more problem data objects describing problems that are specific to the end user's computer system configuration. The targeted problem set 426 can be used to determine targeted technical solutions that were previously developed and vetted and that relate to the particular problem identified with the specific end user's 416 computer system. In some embodiments, the problem data objects of the filtered problem set 426 include links to associated solutions in the approved solutions 360. In other embodiments, a key word search is performed on the approved solutions 360 using key words from the filtered problem set and/or using system-specific parameters 420. The output is a targeted solution set 430 with one or more technical solutions 432 that are targeted to end user's 416 computer system. In embodiments that use an adjustable filter tolerance as described above, the targeted solutions 432 of the targeted solution set 430 may be more or less targeted.

The targeted solution set 430 is then made available to the specific end user 416. In one embodiment, a targeted solution 432 is transmitted (e.g., pushed) to the end user 416 by the agent 422. In other embodiments, the technical solution 432 may be stored at a web site location where the end user 416 can retrieve it. In the latter embodiment, the agent 422 can transmit a hypertext link to the end user 416 that links to the stored technical solution 432.

FIG. 5 illustrates a global problem and solution identification process 402 and a specific targeted solution determination process 404, much like those shown in FIG. 4. Generally, the modules and processes are the same as those shown in FIG. 4. However, in the embodiment shown in FIG. 5, the filtering of the problem set and solution determination is performed by the agent 422. In this embodiment, the agent 422 applies the filtering based on agent-assessed end user system-specific parameters 518.

FIG. 6 illustrates an exemplary scheme 600 for delivering network-based technical support to an end user in accordance with one embodiment. In this scheme 600, an end user client X 602 associated with a subscribing end user identified by ‘X’, where ‘X’ may be a unique end user identifier, interacts with a technical support services architecture (e.g., technical support services architecture 206, FIG. 2) to obtain technical support. A dynamic web page generator 604 of the technical support services architecture dynamically generates targeted web pages that may be browsed by the end user client X 602. An agent 603 may facilitate problem identification an solution determination. In one embodiment, the dynamic web page generator 604 is one of a plurality of tools (e.g., KB system & tools 232, FIG. 2) accessible through the technical support services architecture.

In one embodiment one or more solutions, which can be approved solutions 606 or potential solutions 607, are identified from the solutions set 360 in the technical support service architecture 300. The dynamic web page generator 604 dynamically generates one or more web pages 608 based on the identified approved solutions 606 and/or potential solutions 607. In one embodiment, the solutions 606 comprise one or more eXtensible Markup Language (XML) documents and the dynamic web page generator 604 transforms the XML documents into browsable pages, such as Hypertext Markup Language (HTML) web pages using XSLT.

The dynamic web page generator 604 may use the system configuration file 610 associated with end user X subscription 612 to select content 614 or text for the web pages 608, or otherwise adapt the web pages 608 to end user X's particular computer system. Content 614 may be stored in a content data store 616 that store content applicable to a general population of end user systems, and wherein content is selectable for inclusion in web pages 608 describing solutions targeted at end user X's particular system configuration. Web pages 608 typically reference one or more items of content 614. Examples of content are images, photos, audio, or media related to parameters or system components of end user X's system. Web pages 608 may be stored in association with end user X's subscription 612, and can be accessed by end user client X 602. In other embodiments, web pages 608 may be stored in other memory.

The dynamic web page generator 604 creates a link 618 (e.g., a hyperlink) to each web page 608. The link 618 may be transmitted to the client 602 by the technical support services architecture. Alternatively, the link 618 may be transmitted to the technical support technician/agent 603, who may then transmit the link 618 to the end user client 602. The end user client 602 may also retrieve the link 618 from the technical support services architecture. The link 618 may be transmitted while the end user is online or offline.

Links 618 are first stored in either a new solutions folder 620 or potential solutions folder 621, depending on whether the solution is approved or potential. From the folders 620, 621 the client 602 can access them for browsing the corresponding web pages 608. After the client 602 browses the corresponding web pages 608, the links are moved to a used solutions 622 folder. The client 602 can access both new solutions and old solutions through links in the new solutions folder 620 and used solutions folder 622.

FIG. 7 illustrates a configuration difference scheme 700 whereby a configuration difference generator 704 of the technical support services architecture (e.g., technical support services architecture 300, FIG. 3) generates a configuration difference 706 indicating differences in system parameters between two configurations of end user X's system. The end user client X 602 generates and transmits a latest configuration 708 to the technical support services architecture. The configuration difference generator 704 receives the latest configuration 708 and compares the latest configuration 708 to the last acquired configuration 610.

Based on the comparison, a difference configuration 706 is generated. The difference configuration 706 in general includes system parameters with associated indicators that indicate whether the system parameters have been added or removed. The difference configuration 706 may include only the differences between the configurations. Alternatively, the difference configuration 706 may comprise a baseline configuration, such as the latest configuration 708 or the last acquired configuration 610, edited to include indicators indicating whether parameters have been added or removed.

The end user client 602 receives the difference configuration 706, whereupon the end user client 602 may store the difference configuration 706 and/or use the difference configuration 706 to generate a prior configuration 710. The prior configuration 710 and the latest configuration 708 may be viewed by the end user.

FIG. 8 is a flowchart illustrating a process 800 for registering a customer for technical support using the technical support platform according to one embodiment. The customer enters the process through a web site or web portal at an entry step 802. After the customer enters the web portal, it is determined whether the customer is an existing customer or if the customer is a new customer at an inquiry step 804. The inquiry step 804 determines if the customer has previously registered to receive customer technical support.

If the customer is registered, the process 800 branches “Yes” to a login process 806. In the login process 806, the customer logs in with, for example, a username and password. A verification step 808 verifies the customer login information by accessing a customer account master subscription database 810, which has registered customer login information stored therein. If the customer login information is valid, the process 800 branches “Yes” to display step 812, which displays approval of the customer's account registration.

Referring again to the inquiry step 804, if the use is not an existing customer, the process 800 branches “No” to a registration step 814. Also, if in the verification step 808 it is determined that the customer's login information is invalid, the process 800 branches “No” from the verification step 808 to the registration step 814. The registration process 814 gathers customer registration information using a registration input form. A registration data collection step 816 collects the registration data entered into the input form.

An E-commerce process 818 provides functionality related to purchase and distribution of services over the network. E-commerce includes, without limitation, sales, marketing, billing, payment, fulfillment, and/or entitlement. E-commerce may be conducted between, businesses, governmental agencies, individual consumers, or others. In accordance with embodiments described herein, E-commerce includes, without limitation, up-selling, cross-selling that can be performed by service providers.

After the account approval is displayed in deployment and display step 812, the process 800 deploys one or more application(s) (e.g., client applications) to the end user. The applications can be Flash applets, or others. The application(s) collects and validates the customer's system parameters in an inventory step 820. By way of example, but not limitation, inventory step 820 may gather the customer's system configuration, component information, system state information, usage capabilities, requirements, or other information. The inventory step 820 then validates the system parameters. If valid, the process 800 branches “Yes” to integration process 822.

The integration process 822 employs direct client data transfers 824 and sequential data transfers 826 to collect and integrate customer system parameters, which are determined via the “configuration detector” applet to find both hardware devices and software applications; entering the relevant system information into a stored application database 828. A system profile of the end user's system configuration is sent to the technical support services architecture 829. The integration process 822 can involve the technical support services architecture 829 automatically determining whether the user had previously run the configuration detection process to gather the user's system configuration, and, if so, comparing the most recent system configuration profile with the last system configuration profile. Differences between the two profiles are determined. The new profile, the differences, and/or the old profile can be sent to the client so that the client has a history of the system configuration.

In addition, based on the user's system configuration, system-specific help and resolutions are sent to the client. The system-specific help and resolutions are determined by filtering the knowledge base with the user's system configuration to determine only those data sets in the knowledge base that are relevant to the user's system. The filtering is performed on a machine identifier basis, rather than a customer identifier basis to support multi-computer users, businesses, and households.

If the inventory operation 820 determines that the system parameters are insufficient to provide for integration, the process 800 branches “No” to a customer interaction step 830. The customer interaction step 830 involves customer use of the deployed application(s) to determine the cause of technical problems that exist at the client computing device. The deployed application(s) interact with the technical support provisioning center to resolve the technical problems. For example, additional software may be transferred from the technical support services architecture 829 to the client. As another example, the client may receive information from the knowledge base to facilitate problem resolution. Any number of resolutions may be provided to the client. These may be provided while the client is on-line or when the client is offline. If resolutions are provided offline, the end-user can access them later when the client comes online. For example, the end-user may be notified by the client that new resolutions are available. After the interaction operation 830, the process 800 branches to the integration process 822, which integrates the customer system parameters as described previously.

FIG. 9 is a flowchart illustrating and embodiment of a technical solution algorithm 900 that may be carried out by an end user client, such as end user client 109 of FIG. 1. In one embodiment, the algorithm 900 is performed by an end user client that is in communication with one or more applications, applets or other tools executing on a technical support services architecture, such as technical support services architecture 206 of FIG. 2.

In a generating operation 902, a system configuration is automatically generated. The generating operation 902 gathers system-specific parameters associated with the end user computer system and stores the parameters into a configuration file. The generating operation 902 may occur when the system powers on and/or when the end user logs into the technical support services architecture to obtain technical support. The generating operation 902 can gather the parameters in different ways. For example, the generating operation 902 may read a registry of hardware and software components residing on the end user system. The generating operation 902 may query different hardware and software components to obtain further details about the components, such as versions, models or configuration.

A transmitting operation 904 transmits the configuration file including system-specific parameters to the technical support services architecture. The transmitting operation 904 may occur automatically without the end user being notified, or the transmitting operation 904 may notify the end user prior to transmitting. Further the transmitting operation 904 may wait for end user approval prior to transmitting the configuration file.

A receiving operation 906 receives configuration difference information from the technical support services architecture. The configuration different information may be in the form of a difference file. The configuration difference information indicates a delta between the configuration generated in the generating operation 902 and the last most recent system configuration. For example, software or hardware components may have been removed or disabled since the last time the configuration was transmitted to the technical support services architecture.

In another generating operation 908, an end user client application uses the configuration difference information to generate a prior configuration file including hardware and software parameters of the prior system configuration. In one embodiment, the generating operation 908 starts with the current configuration (i.e., the configuration generated in operation 902) and adds new parameters from the difference set of configuration parameters and deletes parameters that are indicated as not present in the difference set of parameters.

In a presenting operation 910, the current system configuration and the prior (last most recent) system configuration are presented. The end user can select which configuration to view and/or the two configurations may be presented side-by-side. Alternatively, one of the configurations may be presented with differences highlighted with different colors (e.g., red for deletions, blue for additions). In one embodiment, one or more of the current and prior configurations are presented in a window pane that is positioned next to a chat window pane in an integrated graphical user interface window. In such an embodiment, the end user can view both configurations while chatting with a technical support technician/agent.

In a receiving operation 912, the end user client receives one or more interactive links to web pages. The links may be hyperlinks that the user can select (e.g., “click on” with a mouse input device). The interactive links may be transmitted (e.g., pushed) to the end user client from the technical support services architecture or a technical support technician/agent. The links may be transmitted to the end user while the end user is online, for example during a chat session, or while the end user is offline. When links (or other information) are sent to the end user when the end user is offline, such as when the end user system is powered off, the end user can retrieve the links (or other information) later by the end user client from a designated inbox or other repository.

When the end user selects an interactive link, a browser navigates to the associated web page in a navigating operation 914. In one embodiment, the web page resides in memory at the technical support service architecture. The web pages can include various types of information related to the end user's computer system. In one embodiment the web pages instruct the end user of targeted solutions to solve a problem exhibited by the end user's system. The web pages may also include problem descriptions specific to the end user's system. Content of the web pages is targeted to the end user's particular system configuration. For example, images or photos of particular system components (e.g., USB cables, routers, printers, disk drives) specific to the end user's computer can be included in the web pages. As another example, audio (e.g., .wav, .mp3, .rm) may be included on the web pages that provides system-specific instructions to the user. Such images, photos, audio or other content can help the end user more readily identify particular hardware and software components and adjust them in a way to solve a technical problem.

In a storing operation 916, links to web pages that have been browsed are stored in a folder (or other memory designation) containing old solutions, and links to web pages that have not been browsed are stored in a folder containing new solutions.

FIG. 10 is a flowchart illustrating an embodiment of a technical support algorithm 1000 that could be carried out by an end user, such as end user 118 of FIG. 1. In a contacting operation 1000, the end user contacts a remote agent. The contacting operation 1002 may involve navigating to a particular web site and establishing a technical support chat session with a technical support agent. For example, the end user may access end user web portal API 344 and/or the chat system 348 of the platform 300 shown in FIG. 3. The technical support agent will also access the chat system 348 of the platform 300.

In an identifying operation 1004, system-specific parameters of the end user computer system are gathered. The system-specific parameters characterize the configuration of the end user computer system. The identifying operation 1004 may involve reading system parameters from various sources in the end user computer system and storing them in a system configuration file. Alternatively, the identifying operation 1004 may involve identifying a configuration file associated with the end user in the knowledge base 356 of the platform 300. In a transmitting operation 1006, the system-specific parameters are communicated to the remote agent. The transmitting operation 1006 may involve the end user sending the system-specific parameters or the database driver 370 sending the end user-specific configuration file to the agent.

After receiving the system-specific parameters, the agent may determine one or more targeted solutions for a problem associated with the end user computer system. The targeted solutions may comprise XML files, factored content data, and re-factored potential solutions data, structured and unstructured content, from within the knowledge base solutions set 360 of FIG. 3. The process of factoring content refers generally to any one or more of creating content, modifying content, regenerating content.

The dynamic web page generation includes dynamically assembling parts of the web page, including content. An extensible style sheet language transformation (XSLT) process may be applied to the XML files to generate customizable and stylized HTML based content in representation of the targeted solutions. XML queries and data driven results sets may be applied to and through the XSLT transformational process for factoring and re-factoring content into forms other than HTML in support of providing solution sets in various other native formats or style sheets. The targeted solution that is generated consists of content that can be presented at the end user. This content may include images, text, video, audio, or other content that is relevant to the end user computer system's particular configuration and/or problem set. For example, if the solution relates to a cable connection, an image of a cable having the particular connection types may be included in the solution so that the customer can tell what type of cable he needs for his particular system.

In a receiving operation 1008 the end user receives content representing one or more targeted solutions. In one embodiment, the receiving operation 1008 involves the agent pushing a hyperlink referencing the targeted solution content to the end user. In another embodiment, targeted solution content may be sent to the end user in the form of a document (e.g., a browsable web page). In a storing operation 1010, content representing the targeted solution(s) is stored in a manner that the end user can retrieve the content to view and implement the targeted solution(s). In some embodiments, the targeted solution(s) are first saved as web pages in a file folder of available targeted solutions. Once the end user accesses and implements the content associated with the available targeted solutions, the content is moved to a solutions history folder storing a history of implemented solutions. In a browsing operation 1002, the end user can browse the content representing the targeted solutions.

FIG. 11 is a flowchart illustrating an embodiment of an agent side technical support algorithm 1100 that could execute in conjunction with the end user algorithm 1000 shown in FIG. 10. In a receiving operation 1102 the agent receives an incident report reporting a problem exhibited by the end user's computer system. In a creating operation 1104, a new problem incident ticket is created if a ticket has not been created yet for the reported incident. The ticket uniquely identifies the technical support job carried out in response to the reported incident. The ticket may be any unique identifier such as a series of alphanumeric characters. If a ticket was previously created, the predetermined ticket is user.

In another receiving operation 1106, the technical support agent receives system-specific parameters characterizing the hardware and software configuration of the end user's computer system. As discussed, the system-specific parameters may be delivered in the form of a configuration file from the end user computer system or a stored set of configuration files, such as the end user subscriptions 356.

A determining operation 1108 determines one or more possible causes of the problem reported by the end user. The determining operation 1108 could simply rely on the agent's own knowledge; for example, the technical support agent may be familiar enough with the system-specific parameters that he can recognize the problem and its cause himself. However, in general the agent queries a knowledge base 358 of problem information in the technical support platform 300. The problem information includes sets of problem identifiers with their associated problem descriptions and possible causes. The agent may perform keyword searches using words from the problem description in the incident report or words provided by the end user or other words selected by the agent. The knowledge base 358 returns problem identifiers, problem descriptions and/or possible causes based on the keywords and the system-specific parameters. Any problems returned by the technical support platform 300 are filtered according to the system-specific parameters so that they are targeted to the end user computer system.

In another determining operation 1110 one or more possible solutions are determined that address the one or more causes to the problem. In one embodiment, problems identified in the knowledge base 358 are linked to solutions in the solutions set 360. In this embodiment, the solutions linked to the problems having causes specific to the end user's computer are sent to the technical support agent.

In another embodiment the determining operation 1110 searches a set of stored pre-developed and validated solutions, such as solutions set 360, using key words related to the problem or its possible causes. Any solutions that found during the search are filtered based on the system-specific parameters of the end user's computer system, to derive one or more possible solutions that are targeted to the end user's computer system.

In a generating operation 1112, content is dynamically generated that can be used for presenting the one or more targeted solutions. In one embodiment, XML pages of the targeted solutions are translated using XSLT. The generated targeted solution content is then made available to the end user. In one embodiment the targeted solution(s) content is sent to the end user via e-mail. In another embodiment, the end user is sent a hyperlink the references a targeted solution content. A presenting operation 1114 presents the targeted solution content at the end user's computer system. In one embodiment, the targeted solution content is presented when the end user selects it for presentation (e.g., selecting an associated hyperlink). In some embodiments, the targeted solution content is stored in a file folder storing available solutions. The end user can access the available targeted solutions through the file folder of available solutions. After the user accesses the content related to the available targeted solutions the targeted solution content is moved to another file folder that stores a history of accessed targeted solutions.

User Interface Screenshots

FIG. 12 is a snapshot of a user interface through which a customer can interact with an agent during a technical support session while viewing technical support related information in an integrated window 1200 in accordance with one embodiment. The window 1200 integrates a technical support chat window pane 1202 with a technical support information browser window pane 1204. Through the chat pane 1202 the customer can engage in a technical support session in the form of a chat session with a technical support agent. Chat messages from each chat user are separated into clearly delineated sections 1206 of the pane 1202, and each message is clearly identified with the person who sent the message. In the illustrated embodiment, for example, the name and role 1208 of the chatter are indicated at opposite sides of their respective delineated sections 1206. Further, in some embodiments, chat pane message sections 1206 have different background colors for different chatters to further distinguish messages from each of the chatters.

Turning to the technical support information browser window pane 1204, a variety of browsable information can be presented therein. In the illustrated embodiment, a home page, a dashboard, system configuration information, technical solutions, a technical support history, and settings can be viewed in the technical support information pane 1204. When the user selects the system configuration button, hardware and software parameters associated with the user's computer system are presented in a tree structure 1210. By clicking on higher levels of the tree, the user can “dig deeper” into the configuration parameters. If the user selects the technical solutions button, currently available technical solutions are presented for the user to implement. These technical solutions are typically ones that were previously sent (e.g., pushed) to the user's computer by a technical agent or the technical support platform.

By selecting the history button, the user can view the history of technical solutions that have been implemented. This may be particularly helpful if, for example, a technical solution is implemented and some other problem occurs; the agent and user can more easily determine the cause of the problem by viewing the history of technical solutions. Further, in many cases, technical solutions that were previously implemented can be reversed by undoing the steps of a technical solution shown in the history.

FIG. 13 is a snapshot of a Dashboard graphical user interface 1300 that may be presented by the end user client application in accordance with one embodiment. The GUI 1300 includes functionality for Anti-Virus/Security/Spyware, One Click & Automated Fixes. Via the exemplary GUI 1300, the end-user may click on any one of the options to trigger the corresponding action. For example, selecting “Run an Anti-Virus Program” causes the client application to automatically search, retrieve and launch the loaded and configured Anti-Virus program resident on the end-user computer. If the end-user computer does not have an operating version of the particular type of event driven application such as an AV program, the client application has the ability to present (e.g., pop-up) a message that is able to offer the end-user with the option to purchase and operate a working version of the relevant application type.

FIG. 14 illustrates another GUI 1400 presented by the end user Client Application in accordance with one embodiment. More specifically, the GUI 1400 presents another state of Dashboard providing access to Browser and Internet and/or One Click & Automated Fixes. In this exemplary embodiment and scenario, the end-user, the end-user may click on any one of the options such as “Clear your Browser History” and the client application will responsively perform a one-click fix and automatically complete all of these steps required to perform this particular solution operation.

FIG. 15 illustrates another GUI 1500 that may be presented by the end user Client Application in accordance with one embodiment. In this embodiment and scenario, when the end user selects option “Repair Wireless Connection”, the client application responsively performs a one-click fix and automatically completes one or more steps required to perform this particular solution operation (e.g., repair the wireless connection).

FIG. 16 is a snapshot of yet another GUI 1600 presented by the end user Client Application in accordance with one embodiment. In response to the user selecting an option such as “Defragment your Hard DiskRepair”, the client application launches another applet selection window (e.g. Run Defrag) that will allow the end-user to select the appropriate hard drive to perform the automated solution (e.g., Defragment) and automatically complete all of the steps required to perform this particular service operation.

FIG. 17 is a snapshot of another GUI 1700 presented by the end user Client Application in accordance with one embodiment. In this embodiment and scenario, the end-user, via client application interface listed under the My System option, has the capability to review the CURRENT state of the user's system, which includes a complete Hardware and Software Inventory. Once the end user has reviewed the current state the end user may drill down on any item such as a specific printer (e.g. Printer—HP Office 7200 series). In this instance the end-user could have received problem and solutions sets specifically related to this model of printer that they are using on their current system. However, as the diagram shows in this particular scenario this user does not have the “Filtered Help” feature enabled as part of the user's license. The end-user is automatically prompted to obtain the necessary license to use “Filtered Help”. For example, the end user is given an option to purchase a “premium” subscription of license for the client application and have this feature enabled.

FIG. 18 is a snapshot of another GUI 1800 that can be presented by the Client Application in accordance with one embodiment. This scenario illustrates the functionality to purchase special features. For this embodiment and sample, the end-user, via client application interface, the end-user may purchase an advanced and/or premium client application license that has one or more additional features enabled for their use. The end-user may make this purchase through an embedded and full secured and encrypted E-Commerce Purchasing Module (Process) that at the completion of the purchase will automatically activate the additional features and functionality based on the enhanced subscription and/or client application license they chose to acquire.

FIG. 19 is another snapshot of another GUI 1900 presented by the Client Application in accordance with one embodiment. In this scenario a feature set is activated. For this embodiment and sample, the end-user, via client application interface listed under the My System option, has the capability to review the CURRENT state of their system, which includes a complete Hardware and Software Inventory. Once they have reviewed their current state they may drill down on any item such as a specific printer (e.g. Printer—HP Office 7200 series). In this instance the end-user is able to drill down on their specific printer listed in their inventory, and they are immediately presented with the Filtered Help response, that states there are 15 Solutions to printer problems that are relevant to this make and model printer type.

FIG. 20 illustrates yet another GUI 2000 presented by the Client Application in a particular embodiment. FIG. 20 illustrates a scenario involving Filtered Help and Drill Down Capability. For this embodiment and sample, after the end-user is presented with the number of relevant solutions sets that are available for their particular hardware and/or software (e.g. HP Printer 7200 series) problem, the end-user may drill down to the next step in the Filtered Help problem/solution discovery process and they are presented with a series of problem types. Once the end-user selects what is believed to be the problem, the client application interface presentation screen is automatically updated with a series of combined problem/solution set selectable options, In this diagram the end-user has highlighted “Bent Pin Cable”. Once the end-user clicks on this selection they will activate the dynamic generation of the appropriate Filtered Help solution response for use.

FIG. 21 is another snapshot of another GUI 2100 presented by the Client Application illustrating a scenario involving Filtered Help and Solution Presentation via Embedded Micro-Browser. For this embodiment and sample, the end-user clicks on the “Bent Pin Cable” problem/solution item and this activates the dynamic content generation Process To pull together all of the correct text, images, and structured presentation layer(s) to present a viewable and scrollable solution to the end-user for problem resolution. The dynamically generated content pulled via the Filter Help process and functionality is presented to the end-user via a operating system and browser independent “micro-browser, which is an embedded applet within the framework of the client application interfaces.

FIG. 22 is another snapshot of another GUI 2200 presented by the Client Application illustrating an inventory process showing State, Differences, Problems Selections. For this embodiment and sample, the end-user, via client application interface listed under the My System option, has the capability to review the CURRENT state of their system, which includes a complete Hardware and Software Inventory. The end-user may also view their previous state of their computer system to determine changes since last time they ran the Client Application Diagnostics and System Inventory Reporting assessment and testing components. The end-user may choose to be shown the differences in there CURRENT and PREVIOUS state via a selection option within the client application Interface, to which specific hardware and/or software changes will me immediately displayed for end-user review and usage. End-user may also click on the “Show me only PROBLEMS” selection option and they will be provided with a list of any discovered system and/or software failures, such as drivers, application and hardware device errors.

FIG. 23 is another snapshot of another GUI 2300 presented by the—Client Application illustrating Drill Down & Keyword Search Help. For this embodiment and sample, the end-user, via client application interface listed under the Solution section, the end-user may choose to either drill down and search solutions relevant to a specific problem or the end-user may request a chat communication with a technical support agent (e.g. end-user is chatting with the agent) who is capable of assisting in the diagnosing and resolving of the specific problem communicated by the end-user. This agent has the capability to push a solution or series of solutions (solutions sets) to the end-user for them to utilize to resolve the specific issue or set of issues identified.

FIG. 24 is another snapshot of another GUI 2400 presented by the Client Application involving Keyword Search Help. For this embodiment and sample, the end-user, via client application interface listed under the Solution section, the end-user may choose to search the Knowledge Base System utilizing and intelligent keyword search approach. In this diagram the end-user has selected that his issue is hardware related, and then typed in “tape” into the search field. As quickly as the search field is populated the client application, communicating via the service oriented architecture communications layer, accesses the forward looking search capabilities of the KB System and presents a list of known problem type issue relevant to the tape drives. At this point the end-user may select the problem set most relevant to them and the KB System will report back a series of likely match solutions and/or solutions sets. Once the user finds the most appropriate solutions and/or solutions sets they may activate them by clicking on them. At this point solutions are presented via the micro-browser for immediate review, use and application against the identified problem(s).

Exemplary Computing Device

FIG. 25 depicts a general computing device upon which a technical support delivery platform or portions thereof, may be implemented, accessed, and/or executed. The components computing device 2500 are illustrative of components that client and server computers typically include. As such, the embodiments of the client application described herein can be implemented on the computing device 25. In any particular implementation, more or fewer than those components shown may exist. In addition, components shown may be combined or rearranged in any particular implementation, without departing from the scope of the present invention.

As discussed herein, embodiments of the present invention include various steps. A variety of these steps may be performed by hardware components or may be embodied in machine-executable instructions, which may be used to cause a general-purpose or special-purpose processor programmed with the instructions to perform the steps. Alternatively, the steps may be performed by a combination of hardware, software, and/or firmware.

According to the present example, the computing device 2500 includes a bus 2501, at least one processor 2502, at least one communication port 2503, a main memory 2504, a removable storage media 2505 a read only memory 2506, and a mass storage 2507. Processor(s) 2502 can be any know processor, such as, but not limited to, an Intel® Itanium® or Itanium 2® processor(s), or AMD® Opteron® or Athlon MP® processor(s), or Motorola® lines of processors. Communication port(s) 2503 can be any of an RS-232 port for use with a modem based dialup connection, a 10/100 Ethernet port, a Gigabit port using copper or fiber, or a Universal Serial Bus (USB) port. Communication port(s) 2503 may be chosen depending on a network such as a Local Area Network (LAN), Wide Area Network (WAN), or any network to which the computing device 2500 connects. The computing device 2500 may be in communication with peripheral devices (not shown) such as, but not limited to, printers, speakers, cameras, microphones, or scanners.

Main memory 2504 can be Random Access Memory (RAM), or any other dynamic storage device(s) commonly known in the art. Read only memory 2506 can be any static storage device(s) such as Programmable Read Only Memory (PROM) chips for storing static information such as instructions for processor 2502. Mass storage 2507 can be used to store information and instructions. For example, hard disks such as the Adaptec® family of SCSI drives, an optical disc, an array of disks such as RAID, such as the Adaptec family of RAID drives, or any other mass storage devices may be used.

Bus 2501 communicatively couples processor(s) 2502 with the other memory, storage and communication blocks. Bus 2501 can be a PCI/PCI-X, SCSI, or USB based system bus (or other) depending on the storage devices used. Removable storage media 2505 can be any kind of external hard-drives, floppy drives, IOMEGA® Zip Drives, Compact Disc-Read Only Memory (CD-ROM), Compact Disc-Re-Writable (CD-RW), Digital Video Disk-Read Only Memory (DVD-ROM).

The functional modules, systems, operations, and data structures discussed herein are capable of combination, separation, or any other type of rearrangement without departing from the spirit scope of the invention. For example, the data structures illustrated in the technical support platform 300 of FIG. 300 may each comprise one or more databases, or, in some cases, multiple data stores may be physically implemented in the same database. Data stored in the data stores can be implemented in any format as may be suitable for the particular implementation including, but not limited to, extensible markup language (XML), extensible stylesheet language (XSL), and extensible hypertext markup language (XHTML) as entries in a relational database, flat files, object-oriented, or a proprietary format. Inclusive of these data storage formats is the use of extensible stylesheet language transformation (XSLT) for purposes of defining structured input and outputs from the various data stores.

Various modifications and additions can be made to the exemplary embodiments discussed without departing from the scope of the present invention. For example, while the embodiments described above refer to particular features, the scope of this invention also includes embodiments having different combinations of features and embodiments that do not include all of the described features. Accordingly, the scope of the present invention is intended to embrace all such alternatives, modifications, and variations together with all equivalents thereof. 

1. A method for obtaining customer support, the method comprising: transmitting parameters specific to an end user product to a network-based application operable to dynamically generate a web page instructive of a solution to a problem associated with the end user product based on the parameters; receiving an interactive link to the dynamically generated web page; and browsing the dynamically generated web page by selecting the interactive link.
 2. The method as recited in claim 1 further comprising implementing the solution by performing steps instructed in the web page.
 3. The method as recited in claim 1 wherein transmitting parameters specific to the end user product comprises transmitting a differential set of parameters relative to a base set of parameters.
 4. The method as recited in claim 1, wherein receiving an interactive link comprises receiving a hyperlink from a technical support agent during a chat session between the end user and the technical support agent.
 5. The method as recited in claim 4, wherein browsing the dynamically generated web page comprises browsing the web page in a graphical user interface window pane in a window that includes a chat window pane presenting the chat session.
 6. The method as recited in claim 1, wherein the web page includes content specific to the parameters of the end user's product.
 7. The method as recited in claim 6, wherein the content includes one or more of an image of a component specific to the end user's product parameters, audio specifically related to the end user's product parameters, media content specifically related to the end user's product parameters.
 8. The method as recited in claim 1, further comprising receiving one or more other interactive links to respective other web pages instructive of the solution.
 9. The method as recited in claim 1, further comprising storing the one or more other interactive links in a first folder containing links to web pages instructive of solutions that have not been viewed.
 10. The method as recited in claim 1, further comprising: entering key words descriptive of a problem scenario of the end user's product; transmitting the key words to the network-based application operable to determine a one or more targeted possible causes for the described problem, wherein the one or more targeted possible causes are specific to the parameters of the end user's product, and wherein the one or more targeted possible causes are determined by: searching a knowledge base of problem scenarios gathered from a plurality of other end user's to derive one or more general possible causes; and filtering the one or more general possible causes with the parameters of the end user's product; and receiving a description of at least one of the one or more targeted possible causes.
 11. A computer readable medium storing computer executable instructions that cause a computer to carry out a process for providing customer support, the process comprising: receiving parameters specific to an end user product; dynamically generating a web page instructive of a solution to a problem associated with the end user product based on the parameters; generating an interactive link to the dynamically generated web page.
 12. The computer readable medium as recited in claim 11, the process further comprising: identifying a set of possible causes of the problem based on key words descriptive of the problem; filtering the set of possible problems with the parameters, to derive one or more possible causes that are specific to the end user product.
 13. The computer readable medium as recited in claim 12, wherein identifying a set of possible causes comprises searching a knowledge base of problem scenarios identified in a plurality of other end user products to find problem scenarios that relate to the key words.
 14. The computer readable medium as recited in claim 11, wherein dynamically generating a web page comprises selecting content for the web page based on the parameters of the end user product.
 15. The computer readable medium as recited in claim 11, the process further comprising transmitting the interactive link to the end user.
 16. The computer readable medium as recited in claim 15, wherein transmitting the interactive link to the end user comprises transmitting the interactive link when the end user is not online.
 17. The computer readable medium as recited in claim 11, the process further comprising dynamically generating a plurality of web pages instructive of possible solutions to the problem.
 18. The computer readable medium as recited in claim 17, the process further comprising storing the plurality of web pages remotely from the end user's computer system, wherein storing further comprises storing the plurality of web pages in association with a customer support subscription of the end user.
 19. The computer readable medium as recited in claim 18, the process further comprising storing web pages of new solutions in a first folder and storing web pages of previously used solutions in a second folder. 